/** * @file * @brief QK/C (preemptive non-blocking kernel) platform-independent * public interface. * @ingroup qk * @cond ****************************************************************************** * Last updated for version 5.6.0 * Last updated on 2014-12-14 * * Q u a n t u m L e a P s * --------------------------- * innovating embedded systems * * Copyright (C) Quantum Leaps, www.state-machine.com. * * This program is open source software: you can redistribute it and/or * modify it under the terms of the GNU General Public License as published * by the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * Alternatively, this program may be distributed and modified under the * terms of Quantum Leaps commercial licenses, which expressly supersede * the GNU General Public License and are specifically designed for * licensees interested in retaining the proprietary status of their code. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . * * Contact information: * Web: www.state-machine.com * Email: info@state-machine.com ****************************************************************************** * @endcond */ #ifndef qk_h #define qk_h #include "qequeue.h" /* QK kernel uses the native QF event queue */ #include "qmpool.h" /* QK kernel uses the native QF memory pool */ #include "qpset.h" /* QK kernel uses the native QF priority set */ /****************************************************************************/ /* QF configuration for QK */ /*! This macro defines the type of the event queue used for the * active objects. */ /** * @note This is just an example of the macro definition. Typically, you need * to define it in the specific QF port file (qf_port.h). In case of QK, which * always depends on the native QF queue, this macro is defined at the level * of the platform-independent interface qk.h. */ #define QF_EQUEUE_TYPE QEQueue /*! OS-dependent per-thread operating-system object */ /** * @description * The use of this member depends on the CPU. For example, in port to * ARM Cortex-M with FPU this member is used to store the LR. */ #define QF_OS_OBJECT_TYPE void* /*! OS-dependent representation of the private thread */ /** * @description * QK uses this member to store the start priority of the AO, * which is needed when the QK priority-ceiling mutex is used. */ #define QF_THREAD_TYPE uint_fast8_t #if (QF_MAX_ACTIVE <= 8) extern QPSet8 QK_readySet_; /*!< QK ready-set of AOs */ #else extern QPSet64 QK_readySet_; /*!< QK ready-set of AOs */ #endif /****************************************************************************/ /*! QK scheduler */ void QK_sched_(uint_fast8_t p); /*! Find the highest-priority task ready to run */ uint_fast8_t QK_schedPrio_(void); /* public-scope objects */ extern uint_fast8_t volatile QK_currPrio_; /*!< current task priority */ #ifndef QK_ISR_CONTEXT_ extern uint_fast8_t volatile QK_intNest_; /*!< ISR nesting level */ #endif /* QK_ISR_CONTEXT_ */ /****************************************************************************/ /*! QK initialization */ /** * QK_init() is called from QF_init() in qk.c. This function is * defined in the QK ports. */ void QK_init(void); /*! QK idle callback (customized in BSPs for QK) */ /** * QK_onIdle() is called continuously by the QK idle loop. This callback * gives the application an opportunity to enter a power-saving CPU mode, * or perform some other idle processing. * * @note QK_onIdle() is invoked with interrupts enabled and must also * return with interrupts enabled. * * @sa QV_onIdle() */ void QK_onIdle(void); /****************************************************************************/ /*! Priority Ceiling Mutex the QK preemptive kernel */ typedef struct { uint8_t prioCeiling; uint8_t lockNest; } QMutex; /*! initialize the QK priority-ceiling mutex */ void QMutex_init(QMutex * const me, uint_fast8_t prioCeiling); /*! lock the QK priority-ceiling mutex */ void QMutex_lock(QMutex * const me); /*! unlock the QK priority-ceiling mutex */ void QMutex_unlock(QMutex * const me); /****************************************************************************/ /*! get the current QK version number string of the form "X.Y.Z" */ #define QK_getVersion() (QP_versionStr) /****************************************************************************/ /* interface used only inside QP implementation, but not in applications */ #ifdef QP_IMPL #if (QF_MAX_ACTIVE <= 8) #define QK_prioNotEmpty(set_) QPSet8_notEmpty((set_)) #define QK_prioIsSet(set_, p_) QPSet8_hasElement((set_), (p_)) #define QK_prioFindMax(set_, p_) QPSet8_findMax((set_), (p_)) #define QK_prioInsert(set_, p_) QPSet8_insert((set_), (p_)) #define QK_prioRemove(set_, p_) QPSet8_remove((set_), (p_)) #else #define QK_prioNotEmpty(set_) QPSet64_notEmpty((set_)) #define QK_prioIsSet(set_, p_) QPSet64_hasElement((set_), (p_)) #define QK_prioFindMax(set_, p_) QPSet64_findMax((set_), (p_)) #define QK_prioInsert(set_, p_) QPSet64_insert((set_), (p_)) #define QK_prioRemove(set_, p_) QPSet64_remove((set_), (p_)) #endif #ifndef QK_ISR_CONTEXT_ /*! * Internal port-specific macro that reports the execution context * (ISR vs. thread). */ /*! * @returns true if the code executes in the ISR context and false * otherwise */ #define QK_ISR_CONTEXT_() (QK_intNest_ != (uint_fast8_t)0) #endif /* QK_ISR_CONTEXT_ */ #define QACTIVE_EQUEUE_WAIT_(me_) \ (Q_ASSERT_ID(0, (me_)->eQueue.frontEvt != (QEvt *)0)) #define QACTIVE_EQUEUE_SIGNAL_(me_) do { \ QK_prioInsert(&QK_readySet_, (me_)->prio); \ if (!QK_ISR_CONTEXT_()) { \ uint_fast8_t p = QK_schedPrio_(); \ if (p != (uint_fast8_t)0) { \ QK_sched_(p); \ } \ } \ } while (0) #define QACTIVE_EQUEUE_ONEMPTY_(me_) \ QK_prioRemove(&QK_readySet_, (me_)->prio) /* native QF event pool operations */ #define QF_EPOOL_TYPE_ QMPool #define QF_EPOOL_INIT_(p_, poolSto_, poolSize_, evtSize_) \ (QMPool_init(&(p_), (poolSto_), (poolSize_), (evtSize_))) #define QF_EPOOL_EVENT_SIZE_(p_) ((uint_fast16_t)(p_).blockSize) #define QF_EPOOL_GET_(p_, e_, m_) ((e_) = (QEvt *)QMPool_get(&(p_), (m_))) #define QF_EPOOL_PUT_(p_, e_) (QMPool_put(&(p_), (e_))) #endif /* QP_IMPL */ #endif /* qk_h */